In this paper, we have developed a model of the tunneling current through a high- dielectric stack in MOS capacitors with anisotropic masses. The transmittance was numerically calculated by employing a transfer matrix method and including longitudinal-transverse kinetic energy coupling which is represented by an electron phase velocity in the gate. The transmittance was then applied to calculate tunneling currents in TiN/HfSiOxN/SiO2/p-Si MOS capacitors. The calculated results show that as the gate electron velocity increases, the transmittance decreases and therefore the tunneling current reduces. The tunneling current becomes lower as the equivalent oxide thickness (EOT) of HfSiOxN layer increases. When the incident electron passed through the barriers in the normal incident to the interface, the electron tunneling process becomes easier. It was also shown that the tunneling current was independent of the substrate orientation. Moreover, the model could be used in designing high speed MOS devices with low tunneling currents.

Govoreanu B, Blomme P, Rosmeulen M, Houdt J V, Meyer K D. A Model for Tunneling Current in Multi-layer Tunnel Dielectrics. Solid-State Electronics. 2003; 47(6): 1045-1053

Iwai H, Momose H S, Katsumata Y. Si-MOSFET Scaling Down to Deep-sub-0.1-micron Range and Future of Silicon LSI. International Symposium on VLSI Technology System and Applications. 1995; 31: 262-267

Khairurrijal, Noor F A, Abdullah M, Sukirno, Miyazaki S. Theoretical Study on Leakage Current in MOS with High-K Dielectric Stack: Effects of In-plane-Longitudinal Kinetic Energy Coupling and Anisotropic Masses. Transactions of the Materials Research Society of Japan. 2009; 34(2): 291-295

Wilk G D, Wallace R M, Anthony J M. High-k Gate Dielectrics: Current Status and Materials Properties Considerations. Journal of Applied Physics. 2001; 89(10): 5243-5275

Green M L, Gusev E P, Degraeve R, Garfunkel E. Ultrathin (<4 nm) SiO2 and Si-O-N Gate Dielectric Layers for Silicon Microelectronics: Understanding the Processing, Structure, and Physical and Electrical Limits. Journal of Applied Physics. 2001; 90(5): 2057-2121

Copel M, Gribelyuk M, Gusev E. Structure and Stability of Ultrathin Zirconium Oxide Layers on Si(001). Applied Physics Letters. 2000; 76(4): 436-438

Ferrari G, Watling J R, Roy S, Barker J R, Asenov A. Beyond SiO2 Technology: Simulation of the Impact of High-k Dielectrics on Mobility. Journal of Non-Crystalline Solids. 2007; 353(5-7): 630-634

Chiu F –C. Interface characterization and carrier transportation in metal/HfO2/silicon structure. Journal of Applied Physics. 2006; 100(11): 114102-1-114102-5

Pei Y, Ohta A, Murakami H, Higashi S, Miyazaki S, Akasaka T, Nara Y. Analysis of Leakage Current through Ultrathin HfSiOxN/SiO2 Stack Gate Dielectric Capacitors with TiN/W/TiN Gate. International Workshop on Dielectric Thin Films for Future ULSI Devices – Science Technology. Kanagawa. 2006; 107-108

Chowdhury N A, Misra D. Charge Trapping at Deep States in Hf–Silicate Based High-k Gate Dielectrics. Journal of Electrochemical Society. 2007; 154(2): G30-G37

Khairurrijal, Noor, F A, Sukirno. Electron Direct Tunneling Time in Heterostructures with Nanometer-thick Trapezoidal Barriers. Solid-State Electronics. 2005; 49(6): 923-927

Khairurrijal, Mizubayashi W, Miyazaki S, Hirose M. Analytic Model of Direct Tunnel Current through Ultrathin Gate Oxides. Journal of Applied Physics. 2000; 87(6): 3000-1-3000-5

Noor F A, Abdullah M, Sukirno, Khairurrijal. Comparison of Electron Direct Transmittance and Tunneling Time of Si(100)/HfO2/Si(100) and Si(110)/HfO2/Si(110) Structures with Ultra-thin Trapezoidal Barrier. Indonesian Journal of Physics. 2007; 18(2): 41-45

Zhao Y, White M H. Modeling of Direct Tunneling Current through Interfacial Oxide and High-k Gate Stacks. Solid-State Electronics. 2004; 48(10-11): 1801-1807

Wu H, Zhao Y, White M H. Quantum Mechanical Modeling of MOSFET Gate Leakage for High-k Gate Dielectrics. Solid-State Electronics. 2006; 50(6): 1164-1169

Chen W B, Xu J P, Lai P T, Li Y P, Xu S G. Gate Leakage Properties of MOS Devices with Tri-Layer High-k Gate Dielectric. Microelectronics Reliability. 2007; 47(6): 937-943

Kauerauf T, Govoreanu B, Degraeve R, Groeseneken G, Maes H. Scaling CMOS: Finding the Gate Stack with the Lowest Leakage Current. Solid-State Electronics. 2005; 49(5): 695-701

Noor F A, Abdullah M, Sukirno, Khairurrijal, Ohta A, Miyazaki S. Electron and hole components of tunneling currents through an interfacial oxide-high-k gate stack in metal-oxide-semiconductor capacitors. Journal of Applied Physics. 2010; 108(9): 093711-1-093711-4

Mizuno T, Sugiyama N, Tezuka T, Moriyama Y, Nakaharai S, Maeda T, Takagi S. High-Speed Source-Heterojunction-MOS-Transistor (SHOT) Utilizing High-Velocity Electron Injection. IEEE Transactions on Electron Devices. 2005; 52(12): 2690-2696

Abdolkader T M, Hassan M M, Fikry W, Omar O A. Solution of Schrodinger equation in double-gate MOSFETs using transfer matrix method. Electronics Letters. 2004; 40(20): 1-2

Kim K –Y, Lee B. Tunneling Time and the Post-Tunneling Position of an Electron through a Potential Barrier in an Anisotropic Semiconductor. Superlattices and Microstructure. 1998; 24(6): 389-391

Kim K –Y, Lee B. Transmission Coefficient of an Electron through a Heterostructure Barrier Grown on Anisotropic Materials. Physical Review B. 1998. 58(11): 6728-6731

De Vries P L. A First Course in Computational Physics, Second Edition. New York: Wiley. 1993

Szczyrbowski J. A New Simple Method of Determining the Effective Mass of an Electron or the Thickness of Thin Metal Films. Journal of Physics D: Applied Physics, 1986; 19(7): 1257-1263

Yi K S, Quinn J J. Linear Response of a Surface Space-Charge Layers in Anisotropic Semiconductor. Physical Review B. 1983; 27(2): 1184-1990

Yi K S, Quinn J J. Optical Absorpsion and Collective Modes of Surface Space-Charge Layers on (110) and (111) Silicon. 1983. Physical Review B, 27(4): 2396-2411

Rahman A, Lundstrom M S, Ghosh A W. Generalized Effective-mass Approach for n-Type Metal-Oxide-Semiconductor Field-Effect Transistor on Arbitrarily Oriented Wafers. Journal of Applied Physics. 2005; 97(5): 053702-1053702-12

Hasanah L, Abdullah M, Sukirno, Winata T, Khairurrijal. Model of a Tunneling Current in an Anisotropic Si/Si1−xGex/Si Heterostructure with a Nanometer-thick Barrier Including the Effect of Parallel–Perpendicular Kinetic Energy Coupling. Semiconductor Science and Technology. 2008; 23(12): 125024-1-125024-6

Noor F A, Abdullah M, Sukirno, Khairurrijal. Comparison of Electron Transmittances and Tunneling Currents in an Anisotropic TiNx/HfO2/SiO2/p-Si(100) Metal–Oxide–Semiconductor (MOS) Capacitor. 2010. Journal of Semiconductors. 31(12): 124002-1-124002-5

Noor F A, Darma Y, Abdullah M, Khairurrijal. 2010. The Effect of Electron Incident Angle on Transmittance and Tunneling Current in an Anisotropic Metal-Oxide-Semiconductor Capacitor with High- Dielectric Gate Stacks. Asian Physics Symposium 2010 (published in American Institute of Physics (AIP) Conference Proceedings). Bandung. 2010; 1325: 206-209